KR100684211B1 - Rotating apparatus using permanent magnet - Google Patents

Abstract

A rotating apparatus using a permanent magnet is provided to obtain a force of rotation without additional power by making a magnet buried on a first and second magnet wheels with a circle shape, revolving a rotary axis in concurrence with moving the other magnet, having the same pole with the buried magnet, by a magnet board link. In a rotating apparatus using a permanent magnet, a case(101) is formed as a cylinder. First and second magnet wheels(160a,160) are formed as a ring. First to fourth pentagon guide disks(130c,130b,103a,130) have a pentagon summit of first to fifth central points and are positioned on a front and a rear of the first and second magnet wheels(106a,160) as two pairs. A first end unit and a second end unit of a magnet board link are formed on an end of a vertical upper and lower connection units, a magnet board(170a) is installed on the lower connection unit with making the magnet board(170a) inclining forward, a connection bar(176) is formed on an upper one side of the magnet board(170a). The first end unit is inserted into the first central point of the first pentagon guide disk(130c) and the second central point of the third pentagon guide disk(130a) and the second end unit is inserted into the third central point of the second pentagon guide disk(130b) and the fourth central point of the fourth pentagon guide disk(130). A first one direction revolution disk(120) is connected with the connection bar(176) of the magnet board(170a). A second one direction revolution disk(120a), placed between the second pentagon guide disk(130b) and the third pentagon guide disk(130a) and then connected, is connected with the connection bar(176) of the magnet board(170a), wherein the one direction clutch(121) is interposed on the rotary axis(171). A first fixed disk(110) buried on the front rotary axis(171) of the first one direction revolution disk(120) supports the rotary axis(171). An idling disk(150), buried on the rear rotary axis(171) of the fourth pentagon guide disk(130), rotates idly by interposing a bearing on the rotary axis(171). A second fixed disk(110a) buried on the rear of the idle disk(150) supports the rotary axis(171).

Description

Power generating device using permanent magnets {ROTATING APPARATUS USING PERMANENT MAGNET}

1 is an internal structure diagram of the present invention,

2 is a front view of a fixed disk according to the present invention;

3 is a front view of the one-way rotating disk according to the present invention;

4 is a cross-sectional view taken along the line “A-A” of FIG. 3;

5 is a front view of the pentagon guide disk according to the present invention;

6 is a cross-sectional view taken along the line “B-B” of FIG. 5;

7 is a front view of the magnet wheel according to the present invention;

8 is a cross-sectional view taken along line “C-C” of FIG. 7;

9 is a perspective view of a magnetic plate link according to the present invention;

10 is a front view of an idle disk according to the present invention,

11 is a cross-sectional view showing a coupling configuration of the present invention,

12 is an exemplary view illustrating an operating state of the present invention, in which a magnetic plate is moved.

FIG. 13 is a state diagram in which the first end of the magnet plate link is moved in the state of FIG. 12.

* Explanation of symbols on the main parts of the drawings *

100: body 101: case

102: rotating shaft 103: connecting pin

110: first fixed disk 110a: second fixed disk

111,151: Bearing 112,122,152: Shaft hole

120: first one-way rotating disk 120a: second one-way rotating disk

121: One-way clutch 123,132,162: Groove

130c: First Pentagram Guide Disk 130b: Second Pentagram Guide Disk

130a: third pentagon guide disk 130: fourth pentagon guide disk

131: central hall 140: moving groove

141: first center point 142: second center point

143: third center point 144: fourth center point

145: fifth center point 141a: first moving home

142a: second moving groove 143a: third moving groove

144a: fourth moving groove 145a: fifth moving groove

150: idle disk 160: second magnet wheel

160a: first magnetic wheel 161: magnet holder

163: magnet 164: central hole

170: magnetic plate link 170a: magnetic plate

171: first end 172: upper connection part

173: arc portion 174: lower connection portion

175: second end 176: connecting rod

The present invention relates to a power generator using a permanent magnet, and more particularly, to a power generator using a permanent magnet to obtain a rotational force using the pulling and pushing force of the permanent magnet.

In general, the atoms that make up matter consist of the nucleus and the electrons, the nucleus is located in the center, and the electrons rotate around the nucleus, which rotates as the earth rotates around the solar system.

Due to the rotation of the electrons, the material has the properties of a magnet, but since the magnetic regions of the atoms constituting the material are arranged differently from one material to another, the magnetic properties cancel each other out and become nonmagnetic.

However, in the case of permanent magnets, the atoms form a constant array without canceling the magnetic properties of the respective electrons.

When the same magnets face each other, the permanent magnets generate a force to push each other, and when different poles face each other, a force to attract each other is generated.

Conventionally, the permanent magnet as described above is simply used as an opener or a memo board to be attached to a metal body, and thus the utilization of the pulling force and the pushing force of the magnet is very low.

The present invention has been made in consideration of the above circumstances, and an object thereof is to provide a power generator using a permanent magnet to obtain a rotational force by using the pulling and pushing force of the permanent magnet.

The present invention comprises a case in which a rotating shaft penetrates horizontally in the center while forming a cylindrical shape to achieve the above object; First and second magnet wheels formed in a ring shape, and having magnets embedded in an arc; It has a pentagonal vertex of the first, second, third, fourth, and fifth center points, while the first, second, third, fourth, and fifth moving grooves are formed between each center point, and a pair of two First, second, third, and fourth pentagonal guide discs which are installed at front and rear sides of the first and second magnet wheels, and have grooves on opposite sides thereof; At the ends of the vertical upper and lower connecting portions, the first and second ends are bent at right angles in opposite directions with respect to each other, while the magnetic plates are installed to be inclined forward, and the connecting rods are provided on one side of the upper magnetic plates. And a first end portion is positioned inside each of the first and second magnet wheels, while a first end portion is formed at each of the first center point of the first pentagon guide disk and the second center point of the third pentagon guide disk, A magnetic plate link inserted into each of the third center point of the second pentagon guide disc and the fourth center point of the fourth pentagon guide disc; A first one-way rotating disk connected to the connecting rod of the magnetic plate and arranged with a one-way clutch interposed therebetween; A second one-way rotating disk positioned and connected between the second pentagram guide disk and the third pentagram guide disk and interposed with a one-way clutch interposed on a rotating shaft and connected to a connecting rod of the magnetic plate; A first fixed disk arranged on a front rotation shaft of the first one-way rotating disk and supporting the rotation shaft; An idling disk arranged on a rear axis of rotation of the fourth pentagonal guide disc, the idling disc being formed by interposing a bearing on the axis of rotation to be idle; The present invention provides a power generating apparatus using a permanent magnet which is constructed behind a idle disk and consists of a second fixed disk supporting a rotating shaft.

Next, the present invention will be described in detail with reference to the drawings.

1 shows a power generating device using a permanent magnet according to the present invention, the power generating device main body 100 using the permanent magnet is the first, second fixed disk 110, 110a, first, first 2 unidirectional rotating disks 120, 120a, first, second, third, fourth pentagonal guide disks 130, 130a, 130b, 130c, first, second magnet wheels 160a, 160 ), The magnetic plate link 170, the idling disk 150 is arranged in the rotary shaft 102 is installed horizontally in the center of the case 101.

In order of this, from the right in the drawing, the second fixed disk 110a, the first one-way rotating disk 120, the first pentagon guide disk 130c, the first magnetic wheel 160a, and the second pentagon guide disk ( 130b), the second one-way rotating disk 120a, the third pentagram guide disk 130a, the second magnet wheel 160, the fourth pentagram guide disk 130, the idling disk 150, the first fixed disk 110 The magnetic plate link 170 is installed in the first magnetic wheel 160a and the second magnetic wheel 160, respectively, in order of the first fixed disk 110, the first The second fixed disk 110a supports the rotating shaft 102 with the circumferential surface fixed to the case 101, while the first one-way rotating disk 120 and the second one-way rotating disk 120a are rotated on the shaft 102. Is coupled to the rotation in one direction, the idling disk 150 is to be idling in the rotary shaft (102).

In the above description, the first, second, third, and fourth pentagonal guide discs 130c, 130b, 130a, 130, and the first and second magnetic wheels 160a, 160b have a circumferential surface thereof. It is fixed to the inner surface of the 101 does not rotate, the first and second fixed disks 110, 110a is also fixed to the inner surface of the case 101, the first, second one-way rotating disk 120 120a and the rotating shaft 102 are rotated.

The first and second fixed disks 110 and 110a are formed in a circular plate body as shown in FIG. 2, and a bearing 111 having a shaft hole 112 at the center thereof is coupled to form the same center.

The first and second one-way rotating disks 120 and 120a are formed in a circular plate body as shown in FIGS. 3 and 4, and the one-way clutch 121 having the shaft hole 122 in the center thereof is coupled to form the same center. Five grooves 123 are formed on either side, and the grooves 123 are formed while forming the vertices of the pentagon.

The first, second, third, and fourth pentagonal guide discs 130c, 130b, 130a, 130 are formed in a circular plate body as shown in Figs. 5 and 6, the center hole 131 is the same in the center It is formed penetrating while forming a center, and one side is formed with a moving groove 140 to form a pentagon.

The moving groove 140 has five vertices, the top of which is the first center point 141 in the drawing, and the second center point 142, the third center point 143, and the fourth center point 144 in the clockwise direction. And a fifth center point 145, between the first center point 141 and the second center point 142, the first moving groove 141a is between the second center point 142 and the third center point 143. The second moving groove 142a is between the third center point 143 and the fourth center point 144, and the third moving groove 143a is between the fourth center point 144 and the fifth center point 145. The fourth moving groove 144a is formed between the fifth center point 145 and the first center point 141. And grooves 132 constituting the pentagon as described above is formed on the opposite side.

The first and second magnet wheels 160a and 160 are formed to form a ring shape having a thickness as shown in FIGS. 7 and 8, and the edge of the magnet wheels 161 is a magnet holder 161. A groove 162 is formed in the center and has a predetermined depth, and 23 magnets 163 are formed in the groove 162 so that the magnet 163 has a ring shape. Is achieved.

The magnet 163 has an N pole or an S pole toward the center thereof, and is artificially changed according to the polarity of the front surface of the magnet plate 170a fixed to the magnet link 170. For example, if the front surface of the magnet plate 170a is the N pole, the inner circumferential surface of the magnet 163 is also the N pole. If the front surface of the magnet plate 170a is the S pole, the inner circumferential surface of the magnet 163 is also the S pole. This can be done, but the magnet 163, which is placed in a fixed state, is moved by pushing the magnetic plate 170a.

As shown in FIG. 9, the magnet plate link 170 is a link having a shape of a letter “d”, and the first and second ends 171 and 175 horizontally formed at upper and lower sides thereof face in opposite directions. The second end portions 171 and 175 are connected by an upper connection portion 172 that forms a vertical portion, and a lower connection portion 174. The upper and lower connection portions 172 and 174 are circular arc portions that form a track shape. 173).

The arc portion 173 is formed in the same direction as the magnet plate 170a (orthogonal to the first and second end portions 171 and 175). The rotation shaft is positioned at the center of the magnet plate link 170 when the magnet plate link 170 moves. In order not to interfere with the 102, the first end 171 forms a center when the magnetic plate 170a moves.

In the above, the connecting rod 176 is formed on the upper side of the side of the seat plate 170a in the same direction as the second end 175, the end of the connecting rod 176 is formed, the ring is The first one-way rotating disk 120 and the second one-way rotating disk (120a) is connected to the connecting pin 103 is installed in a ring, the magnetic link 170 is operated as the first one-way rotating disk 120 and the first The one-way rotating disk 120a is operated at the same time. (The connecting rod 176 passes through the central hole 131 of the first pentagonal guide disk 130c and the third pentagonal guide disk 130a. (103).

The idle disk 150 is formed of a circular plate body as shown in Figure 10, the bearing 151 having a shaft hole 152 in the center is coupled while forming the same center.

In the combination of the present invention configured as described above, as shown in FIG. 11, first and second fixed disks 110 and 110a are arranged on both sides of the rotating shaft 102 horizontally penetrating the center of the case 101, and the rotating shaft From the right side of the drawing of 102, the first one-way rotating disk 120, the first pentagonal guide disk 130c, the first magnet wheel 160a, the second angular guide disk 130b, the second one-way rotating disk 120a ), The third pentagram guide disk 130a, the second magnet wheel 160, the fourth pentagram guide disk 130, and the idling disk 150 are assembled in the order of the first one-way rotating disk 120 and the second. The one-way rotating disk 120a is coupled to the rotary shaft 102 and the one-way clutch 121 to rotate only in one direction, and the idle disk 150 is coupled to the rotary shaft 102 and the bearing 151 to idle. The first, second, third, and fourth pentagonal guide discs 130c, 130b, 130a, 130, and the first and second magnetic wheels 160a, 160 are formed on the inner circumferential surface of the case 101. It is fixed.

The first one-way rotating disk 120 is connected to the connecting rod 176 of the magnet plate link 170, and the second one-way rotating disk 120a is connected to the connecting rod 176 of the magnet plate link 170.

The magnet plate link 170 is positioned in each of the inside of the second magnet wheel 160 and the inside of the first magnet wheel 160a, respectively. The magnet plate link 170 is located in the second magnet wheel 160. The first end 171 is inserted into the first center point 141 of the fourth pentagonal guide disk 130 as a central axis, and the second end 175 is the third center point of the third angular guide disk 130a ( 143).

The first end 171 of the magnet plate link 170 located inside the first magnet wheel 160a is inserted into the second center point 142 of the second pentagon guide disk 130b with a central axis, The end 175 is inserted into the fourth center point 143 of the first pentagon guide disk 130c. The center of the front surface of the magnet plate 170a of the magnet plate link 170 faces the 4 o'clock direction, and the upper and lower connecting portions 172 are disposed. While being inclined with respect to the, it has the same polarity as the magnets 163 of the first and second magnet wheels 160a and 160.

As shown in FIG. 12, the operation of the present invention coupled to the fourth angular guide disk 130 may include the first end portion 171, which is the central axis of the magnet plate link 170, located in the second magnet wheel 160. At one center point 141, the second end portion 175 is inserted into the third center point 143 of the third pentagonal guide disk 130a, and the magnetic plate link located in the first magnet wheel 160a ( The first end portion 171, which is the central axis of 170, is connected to the second center point 142 of the second pentagram guide disk 130b, and the second end portion 175 is the fourth center point of the first pentagram guide disk 130c ( 144, the connecting rod 176 of the magnet plate link 170 in the first magnetic wheel 160a is the first one-way rotating disk through the central hole 131 of the first pentagon guide disk 130c. The connecting rod 176 of the magnet plate link 170 in the second magnetic wheel 160 is connected to the connecting pin 103 of the 120 and the ring at the same time. The center hole 131 of the third pentagon guide disk 130a is formed. Through the second one-way rotating disk 120a It is connected to the connecting pin 103 and the ring of the) to start the operation.

In the above state, each magnetic plate 170a is moved while being pushed clockwise by the magnets 163 of the first and second magnet wheels 160a and 160, respectively, in the second magnet wheel 160. The second end portion 175 of the magnetic plate link 170 positioned is moved along the third moving groove 143a of the third angular guide disk 130a with the axis of the first end portion 171 as the central axis. The second end portion 175 of the magnet plate link 170 positioned in the center point 144 and located in the first magnet wheel 160a has a first angular guide disc around the first end portion 171 as a central axis. It moves along the fourth moving groove 144a of 130c and is located at the fifth center point 145.

In the above state, the first end 171, which is the central axis of the magnet plate link 170 located in the second magnet wheel 160, is the second end of the magnet plate link 170 located in the first magnet wheel 160a. 13 moves along the first moving groove 141a by the force of the movement 175 to be located at the second center point 142, and is located within the first magnet wheel 160a by this force. The first end 171, which is the central axis of the magnet plate link 170, is moved along the second moving groove 142a to be positioned at the third center point 143, so that the second one-way rotating disk 120 is disposed on the magnet plate. As the shaft 102 is rotated by the connecting rod 176 of the operation link 170, the connecting rod 176 of the magnet plate link 170 in the first magnet wheel 160a is connected to the connecting pin 103. As the first one-way rotating disk 120a is rotated, the rotating shaft 102 is rotated.

In the above, the magnet plate link 170 in the second magnet wheel 160 is the first one-way rotating disk 120, the magnet plate link 170 in the first magnet wheel 160a is the second one-way rotating disk 120a. Will rotate.

As described above, according to the present invention, the magnets are embedded in the first and second magnet wheels while forming a circle, while the magnets having the same polarity as the magnets are moved by the magnet plate link and the rotating shaft is rotated separately. The effect is that you can get the rotational power without the power.

Claims (1)

A case in which the rotating shaft penetrates horizontally in the center while forming a cylindrical shape; First and second magnet wheels formed in a ring shape, and having magnets embedded in an arc; While having pentagonal vertices of 1, 2, 3, 4, 5 center points, first, 2, 3, 4, 5 moving grooves are formed between each center point, and two pairs of the first and second magnet wheels First, second, third, and fourth pentagonal guide discs installed at front and rear sides and having grooves on opposite sides thereof; At the ends of the vertical upper and lower connecting portions, the first and second ends are bent at right angles in opposite directions with respect to each other, while the magnetic plates are installed to be inclined forward, and the connecting rods are provided on one side of the upper magnetic plates. And a first end portion of each of the first and second magnet wheels, the first end portion of each of the first angular guide disc and the second center point of the third angular guide disc, and the second end of the second magnetic wheel. A magnetic plate link inserted into each of a third center point of the pentagonal guide disc and a fourth center point of the fourth pentagonal guide disc; A first one-way rotating disk connected to the connecting rod of the magnetic plate and arranged with a one-way clutch interposed therebetween; A second one-way rotating disk positioned and connected between the second pentagram guide disk and the third pentagram guide disk and interposed with a one-way clutch interposed on a rotating shaft and connected to a connecting rod of the magnetic plate; A first fixed disk arranged on a front rotation shaft of the first one-way rotating disk and supporting the rotation shaft; An idling disk arranged on a rear axis of rotation of the fourth pentagonal guide disk, the idling disk being interposed with a bearing interposed therebetween to form a bearing; A power generating device using a permanent magnet that is constructed behind the idle disk and consists of a second fixed disk supporting the rotating shaft.

Images